DE102006017389A1 - Refraction measuring device for determining the refractive properties of an eye - Google Patents

Abstract

A distance measuring device determines the distance between the refractometer (1) and the eye (2) of the patient. It measures the distance between the refractometer and the front and/or rear surface of the cornea. A slit projection device (16) is provided for the slit illumination of the eye. A Scheimpflug camera (17) records split images of the eye in which the distance between the refractometer and the eye is derived from the split images via an evaluation device. An independent claim is included for an analyzing system.

Description

The The invention relates to a refraction measuring device for determination the refractive properties of an eye according to the preamble of Claim 1.

Generic refraction measuring devices are often referred to as Autorefraktometer and serve in addition, the refraction of an eye and possibly a refractive error to measure the eye from a distance.

The basic principle of generic Refraktionsmessvorrichtungen is in the US 4,761,070 described. By means of an optical projection device, for example light emitting diodes, a lighting pattern is generated and projected onto the retina of the eye. The projection of the illumination pattern is carried out in particular so that the illumination pattern is focused on the retina. With an optical observer including a photoelectric sensor such as a video camera, the retinal reflected light pattern is viewed through the eye lens so that an imaging pattern is imaged on the photoelectric sensor. This imaging pattern is recorded with the photoelectric sensor and evaluated with an evaluation device, preferably a digital image data processing software. According to the refractive properties of the eye, the illumination pattern projected onto the retina is characteristically distorted, so that by evaluating the degree of distortion, the refractive properties of the eye can be derived.

From greater Meaning of the correct derivation of the refraction properties is that the Eye at a certain distance to the refraction measuring device is arranged. Because distance deviations between eye and refraction measuring device to lead to make the lighting pattern distort differently the photoelectric sensor is mapped so that the distance deviations lead to measurement errors in the refraction determination.

To avoid these measurement errors describes the DE 101 53 397 A1 a refraction measuring system, which additionally has a measuring unit for determining the distance between the device and the patient. The data obtained by the distance measurement can be used to properly position the patient in front of the device. In addition, it is then also conceivable to incorporate the distance information into the evaluation of the refraction measurement method in order to correct the refraction measurement data accordingly.

As possible measuring systems for determining the distance describes the DE 101 53 397 A1 an ultrasonic transmitter and receiver or an optical distance measuring system, in which a light pattern is projected onto the forehead of the subject, in order to measure the distance between the forehead and the measuring system in this way.

A disadvantage of the in the DE 101 53 397 A1 described measuring device is that with the distance measurement described therein, only the distance between the head of the patient and the refraction measuring device can be measured. This measurement is therefore inaccurate and in principle insufficient to properly correct the refraction measurement data, since the position of the head does not provide a clear statement about the position of the eye. The measurement data correction therefore leads to insufficient results.

outgoing From this prior art, it is therefore an object of the present Invention a new refraction measuring device with integrated Propose distance measuring device, which has the disadvantages of the prior art State of the art avoids.

These Task is by a refraction measuring device according to the teaching of claim 1.

advantageous embodiments The invention are the subject of the dependent claims.

The Invention is based on the idea that in the refraction measuring device provided distance measuring device is adapted to the distance between the refraction measuring device and the one to be examined Eye to measure, as it is alone on this distance for the measurement data correction arrives. Only through the use of this distance data for description the distance between eye and refraction measuring device succeeds it to correctly position the patient respectively Correctly correct the measured refraction measurement data.

The Measuring accuracy can be increased even if with the distance measuring device of Distance between the refractometer and the cornea of the eye, especially the anterior surface of the cornea and / or the Rear surface of the Eye, measurable.

alternative or in addition to it, it is particularly advantageous if with the distance measuring device and the distance between the refraction measuring device and the lens of the eye, in particular the front surface of the eye Lens and / or the back surface the lens, is measurable.

In which type the distance measuring device is designed is in principle any. A distance measuring device has proven particularly suitable and accurate proved that a slit projection device for slit lighting of the eye and a Scheimpflugaufnahmeeinrichtung for recording Cross-sectional images of the eye included. By evaluation of the image data the sectional images taken with the Scheimpflugaufnahmeeinrichtung can the distance between the refraction meter and the eye extraordinarily be derived exactly. In particular, the distance measurement is with regard to the front surface or rear surface the cornea and also with regard to the anterior surface respectively posterior surface the lens by evaluating the sectional images possible.

So far in the refraction measuring device a Scheimpflugkamera used for distance determination Of course, this Scheimpflug mechanism can, too to carry out Conventional tachiometric measurement tasks are used. In particular, then so can the thickness of the corneal tissue derived from the sectional images of the eye.

To carry out a correct measurement, it is advantageous that the eye during the Measurement not moved. That is why it is especially advantageous if provided in the refraction measuring a fixation mark is that while the measurement of the eye is fixed, thereby causing unwanted eye movements to avoid.

Around to extend the functional scope of the refraction measuring device, can additionally a second optical projection device and a second optical Projection device and a second optical observation device be integrated into the refraction measuring device, wherein the second optical projection device together with the second optical Observation device and a suitable evaluation to form a keratometer. The design of the measuring marks of the keratometer, which are part of the projection device is basically arbitrary. It is particularly preferred if two collimated luminous points and a substantially circular, non-collimated light strips as measuring marks in the projection device of the keratometer are provided.

to Formation of the collimated luminous dots may preferably light-emitting diodes are used, which are arranged in a tube, wherein the light-emitting diodes in each case lenses are arranged upstream.

Of the circular, non-collimated light strip may preferably be from a circular cylindrical light guide element be generated. The light is thereby from a light source at the rear end side and / or coupled to the cylinder circumference in the light guide element and exits at the front end side of the light guide. As a light source for the circular cylindrical light guide element can in turn light emitting diodes are used, preferably over the circumference of the circular cylindrical Light guide element are distributed.

Which Light source for generating the illumination pattern in the optical Projection device of the refraction measuring device is used, is basically any. In this case, infrared light sources are particularly advantageous proved.

In the optical observer of the refraction measuring device should preferably be provided a pinhole.

The Type of photoelectric sensors in the various observation devices of Refraction measuring device or the Scheimpflugeinrichtung or the keratometer is basically arbitrary. Preferred for this purpose are video sensors are used, which convert the recorded image data into a video signal convert and forward to downstream functional units. Especially inexpensive can the video sensors of chip cameras, in particular CCD chamberas formed become.

The Video signal of the video sensor should preferably be a digital Data format to a digital image data processing in easy way to enable.

Around Simply align the eye to be examined before starting the measurement to be able to or during to be able to observe the investigation should in the refraction measuring device a Einrichtekamera or overview camera be provided. With a suitable arrangement, the Einrichtekamera at the same time as an overview camera while serve the measurement.

So far in the refraction measuring device a keratometer is integrated, The optical observation device of the keratometer can also used as a set up camera or overview camera become.

A embodiment The invention is shown schematically in the drawing and will exemplified.

It shows:

1 : The schematic structure of an embodiment of a Refrakti invention onsmessvorrichtung in overview.

In 1 is the schematic beam path of a refraction measuring device 01 for taking measurements on the eye 02 shown schematically.

To determine the refractive properties of the eye 02 serves an optical projection device 03 and an optical observation device 04 that together with a lens 05 and an evaluation device, not shown, form a Autorefraktor. With the optical projection device 03 can create a lighting pattern on the retina of the eye 02 be projected and focused there. The optical projection device 03 includes a pinhole 06 , a lens 07 and an infrared light source 08 , The optical observation device 04 The author refractor includes a 6-fold pinhole 09 , a deflecting prism 10 , a lens 11 and a CCD camera 12 , The with the CCD camera 12 recorded image data are evaluated in the downstream evaluation, which is designed in the manner of a digital image processing system, to the refractive properties of the eye 02 to determine. For coupling the different beam paths of the optical projection device 03 and the optical observer 04 serves a mirror 13 with pinhole.

Around the eye 02 to be able to fix during the execution of the measurement, comprises the refraction measuring device 01 furthermore an adjustable fixation mark 14 , whose beam path by means of a splitter plate 15 is fed.

To the distance of the eye 02 can be determined relative to the refraction measuring device, a distance measuring device is provided by a slit projection device 16 and a Scheimpflug recording device 17 is formed. The slit projection device 16 and the Scheimpflugaufnahmeeinrichtung 17 are arranged according to the Scheimpflug rule, so that with the Scheimpflugaufnahmeeinrichtung 17 recorded sectional images are suitable for the distance between the refraction measuring device 01 and the eye 02 to be determined by image data analysis. In particular, by image data analysis of the sectional images of the eye 02 also the distance of the refraction measuring device 01 to the cornea of the eye, in particular the front surface or rear surface of the cornea and also the distance of the refraction measuring device 01 to the lens of the eye, in particular the front surface of the lens or the rear surface of the lens, are determined. In addition, the slit projection device 16 together with the Scheimpflugaufnahmeeinrichtung 17 Of course, also for performing normal tachiometric measurements, in particular the measurement of corneal thickness, are used. The slit projection device 16 includes a lens 18 , a slit diaphragm 19 and a slit lamp 20 , The Scheimpflugaufnahmeeinrichtung 17 is according to the Scheimpflug rule angular relative to the eye 02 arranged and includes a lens 21 and a CCD camera serving as a Scheimpflugaufnahmeeinrichtung 22 ,

In addition, in the refraction measuring device 01 another integrated keratometer, which consists of a suitable projection device 23 and an associated optical observer 24 consists. In the optical projection device serve two light emitting diodes 25 as collimated luminous points. A light guide element 26 with assigned LEDs 27 serves as a collimated light strip with circular cylindrical geometry. In the optical observation device 24 is a lens 28 and a CCD camera 29 intended. The CCD camera 29 At the same time, it also serves as a set-up camera and overview camera. Two divider plates 30 and 31 serve the coupling of the beam path of the slit projection device 16 and the optical observer 24 of the keratometer.

Claims (23)

Refraction measuring device ( 01 ) for determining the refractive properties of an eye ( 02 ) of a patient, - with an optical projection device ( 03 ) comprising at least one light source ( 08 ), which generates a lighting pattern, wherein the illumination pattern of the projection device ( 03 ) on the retina of the eye ( 02 ) and in particular can be focused there, - with an optical observation device ( 04 ) comprising at least one photoelectric sensor ( 12 ), with the observation device ( 04 ) on the retina of the eye ( 02 ) reflected illumination pattern viewed through the cornea and the eye lens and as an image pattern on the photoelectric sensor ( 12 ) can be imaged, - with an evaluation device with which the photoelectric sensor ( 12 ) can be evaluated by deriving the refractive properties of the eye, with a distance measuring device for determining the distance between the refraction measuring device ( 01 ) and the patient, characterized in that with the distance measuring device ( 16 . 17 ) the distance between the refraction measuring device ( 01 ) and the eye ( 02 ) is measurable. Refraction measuring device according to claim 1, characterized in that the distance measurement Facility ( 16 . 17 ) the distance between the refraction measuring device ( 01 ) and the cornea of the eye ( 02 ), in particular the front surface of the cornea and / or the posterior surface of the cornea, is measurable. Refraction measuring device according to claim 1 or 2, characterized in that the distance measuring device ( 16 . 17 ) the distance between the refraction measuring device ( 01 ) and the lens of the eye ( 01 ), in particular the front surface of the lens and / or the rear surface of the lens, is measurable. Refraction measuring device according to one of claims 1 to 3, characterized in that the distance measuring device ( 16 . 17 ) a slit projection device ( 16 ) for gap illumination of the eye ( 02 ) and a Scheimpflugaufnahmeeinrichtung ( 17 ) for taking sectional images of the eye ( 02 ), wherein the distance between the refraction measuring device ( 01 ) and the eye ( 02 ) with an evaluation device from the sectional images of the eye ( 02 ) can be derived. Refraction measuring device according to claim 4, characterized in that in an evaluation device from the sectional images of the eye ( 02 ) also the thickness of the corneal tissue can be derived. Refraction measuring device according to one of claims 1 to 5, characterized in that in the refraction measuring device ( 01 ) a fixation mark ( 14 ) provided by the eye ( 02 ) is fixed during a measurement. Refraction measuring device according to claim 6, characterized in that the actual or virtual distance between eye ( 02 ) and fixation mark ( 14 ) is changeable. Refraction measuring device according to claim 7, characterized marked that the actual Distance between eye and fixation mark by adjustment of the fixation mark can be varied in the refraction measuring device. Refraction measuring device according to claim 7, characterized characterized in that the virtual distance between eye and fixation mark by adjusting at least one lens in the beam path between Fixation mark and eye can be varied. Refraction measuring device according to one of claims 1 to 9, characterized in that the refraction measuring device ( 01 ) a second optical projection device ( 23 ) and a second optical observation device ( 24 ) which together with an evaluation device form a keratometer. Refraction measuring device according to claim 10, characterized in that with the projection device ( 23 ) of the keratometer a defined measuring mark on the cornea is projected. Refraction measuring device according to claim 10 or 11, characterized in that the measuring mark collimated two Luminous dots and a substantially circular, non-collimated light strip having. Refraction measuring device according to claim 12, characterized in that the collimated luminous dots in each case by a light-emitting diode arranged in a tube ( 25 ), which is preceded by at least one lens, are generated. Refraction measuring device according to claim 12 or 13, characterized in that the circular, non-collimated light strip of a circular cylindrical light guide element ( 26 ), wherein the light from at least one light source ( 27 ) on the rear end side and / or on the cylinder circumference in the light guide element ( 26 ) is coupled and exits at the front end side of the light guide element. Analysis system according to claim 14, characterized in that several more than the circumference of the circular-cylindrical optical waveguide element ( 26 ) distributed light emitting diodes ( 27 ) serve. Refraction measuring device according to one of claims 1 to 15, characterized in that in the optical projection device ( 03 ) of the refraction measuring device ( 01 ) an infrared light source ( 08 ) is provided for generating the illumination pattern. Refraction measuring device according to one of claims 1 to 16, characterized in that in the optical observation device ( 04 ) of the refraction measuring device ( 01 ) a pinhole ( 09 ) is provided. Refraction measuring device according to one of claims 1 to 17, characterized in that in the optical observation device ( 04 ) of the refraction measuring device ( 01 ) and / or in the Scheimpflugaufnahmeeinrichtung ( 17 ) and / or in the optical observation device ( 24 ) of the keratometer at least one video sensor ( 12 . 22 . 29 ) is provided, wherein the video sensor ( 12 . 22 . 29 ) passes the image data in the form of a video signal. Refraction measuring device according to claim 18, characterized in that the videosenso ren ( 12 . 22 . 29 ) are formed in the manner of a chip camera. Refraction measuring device according to claim 18 or 19, characterized in that the video signal in a digital Data format generated or converted into a digital data format becomes. Refraction measuring device according to one of claims 1 to 20, characterized in that as the evaluation device of the refraction measuring device ( 01 ) and / or the Scheimpflugaufnahmeeinrichtung ( 17 ) and / or the observation device ( 24 ) of the keratometer, a digital image processing system is provided, can be evaluated with the digital image data. Refraction measuring device according to one of claims 1 to 21, characterized in that the refraction measuring device ( 01 ) a set-up camera for the correct orientation of the eye to be examined ( 02 ) and / or an overview camera for observing the eye to be examined ( 02 ) during the examination. Refraction measuring device according to claim 22, characterized in that the optical observation device ( 29 ) of the keratometer can also be used as a set-up camera and / or as an overview camera.